System and method of fabricating an electrochemical device

ABSTRACT

A solventless system for fabricating electrodes includes a mechanism for feeding a substrate through the system, a first application region comprised of a first device for applying a first layer to the substrate, wherein the first layer is comprised of an active material mixture and a binder, and the binder includes at least one of a thermoplastic material and a thermoset material, and the system includes a first heater positioned to heat the first layer.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a division of and claims priority to U.S.patent application Ser. No. 13/617,162, filed Sep. 14, 2012, whichclaims the benefit of U.S. Provisional Patent Application Ser. No.61/647,773, filed May 16, 2012, the disclosures of which areincorporated herein by reference in their entirety.

GOVERNMENT RIGHTS IN THE INVENTION

The U.S. Government has a paid-up license in this invention and theright in limited circumstances to require the patent owner to licenseothers on reasonable terms as provided for by the terms ofSP4701-09-D-0049 CLIN 0002 awarded by Defense Logistics Agency.

BACKGROUND OF THE INVENTION

Embodiments of the invention relate generally to a dry, solvent-freemethod and apparatus for fabricating electrodes and, more particularly,to a method and apparatus for forming lithium electrochemical cells in alithium-ion (Li-ion) battery.

Typically, power sources, such as batteries, capacitors and fuel cellscontain a positive and negative electrode. Depending on the chemistry ofthe power source, manufacturing methods vary. Many methods, such asthose used in the Li-ion industry, include mixing active materials,conductive materials and binders in a wet slurry, using a solvent, andapplying to a substrate. The application may be via doctor blade, rolltransfer coating, slot die or extrusion.

The cast electrodes are then dried in ovens, while the solvent isrecaptured so as not to allow fumes to escape into the environment, orthe solvent is used as supplemental fuel for the drier. This process istime-consuming and expensive. The ovens are usually very large, long,expensive and space-consuming as well. The solvents are typicallyflammable, hard to remove from the chemical structure, bad for theenvironment, and costly to handle correctly, both environmentally andfrom a safety perspective. If solvent recovery is desired the solventneeds to be captured, condensed, cleaned and prepared for reuse ordisposal.

Some known methods of power source manufacturing have moved away fromsolvent slurries on one electrode, but typically still use asolvent-based method on the other electrode. The non-solvent methodusually includes pressing or extruding a mix of active materials,conductive materials and binder into an electrode, which then isattached to a substrate or current collector. Present day manufacturingtechniques therefore limit throughputs, and the cost of such electrodescan be excessive.

The electrodes made through the solvent casting and subsequentextraction typically exhibit good adhesion to the current collector whenthe dried electrode is mechanically coined. The act of solvent castingand subsequent extraction leaves the binder and electrode structureopen, similar to that of a sponge structure. The coining operationcrushes the electrode structure back down leaving a porosity of 30 to50%. Upon wetting with the electrolyte this crushed sponge-likestructure relaxes and exhibits what is commonly referred to as swellingof the electrode. The typical anode binder, known as PVDF-Polyvinylidenefluoride or polyvinylidene difluoride (PVDF), is a highly non-reactiveand pure thermoplastic fluoropolymer produced by the polymerization ofvinylidene difluoride. It is one of the few known binders that do notreadily react at the lithium potential of the anode and thus istypically preferred as a binder in Li-ion batteries.

Some manufactures have tried to develop processes usingpolytetrafluoroethylene (PTFE) and fibrillating the binder as to createa free standing film. This active material loaded free standing film isthen pressed onto a current collector to be made into an electrode. PTFEis not stable at the Lithium ion anode potential so its use is limitedto that of a cathode binder. Other manufacturers have tried to use waterbased binders to create the lithium electrode structure. They havedifficulty with drying the electrode thoroughly to prevent the moisturereacting with the lithium salts, detrimentally affecting the performanceof the resulting battery.

Thus, the preferred method of fabricating Li-ion batteries typicallyincludes a solvent-based method, for at least one electrode, that meetdemanding performance requirements, while also meeting demanding andrigorous life requirements (by exhibiting adequate adhesion to the basematerial). However, because of the costs associated with handling,reclaiming, and ultimately disposing of these environmentallychallenging solvents, the cost of manufacturing Li-ion and othersolvent-based electrodes can be excessive.

Therefore, it would be desirable to design a solvent-free method andapparatus for fabricating electrodes.

BRIEF DESCRIPTION OF THE INVENTION

The invention is a directed method and apparatus for fabricatingelectrodes and, more particularly, for forming lithium electrochemicalcells in a lithium-ion (Li-ion) battery.

According to one aspect of the invention, a solventless system forfabricating electrodes includes a mechanism for feeding a substratethrough the system, a first application region comprised of a firstdevice for applying a first layer to the substrate, wherein the firstlayer is comprised of an active material mixture and a binder, and thebinder includes at least one of a thermoplastic material and a thermosetmaterial, and the system includes a first heater positioned to heat thefirst layer.

According to another aspect of the invention, a solvent-free method ofmanufacturing an electrode includes feeding a substrate through a feedmechanism, applying a first layer comprised of an active materialmixture and a binder to the substrate, wherein the binder includes atleast one of a thermoplastic material and a thermoset material, andheating the first layer with a first heater.

According to yet another aspect of the invention, a computer readablestorage medium having stored thereon a computer program comprisinginstructions which when executed by a computer cause the computer tocause a substrate to feed through an electrode fabrication system via afeed mechanism, apply heat to the substrate via a first heater, andcause a first layer to be applied onto the substrate, the first layercomprised of an active material mixture and a binder, and the binderincludes at least one of a thermoplastic material and a thermosetmaterial.

Various other features and advantages will be made apparent from thefollowing detailed description and the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings illustrate preferred embodiments presently contemplated forcarrying out the invention.

In the drawings:

FIG. 1 illustrates components of a system for forming active electrodematerials on an electrode substrate, according to an embodiment of theinvention.

FIG. 2 illustrates steps for applying a base layer to an electrodesubstrate and one or more electrode layers of active material theretoaccording to embodiments of the invention.

FIG. 3 illustrates a base layer having an electrode formed thereon usingan embodiment of the invention.

FIG. 4 illustrates components of a system for forming active electrodematerials on two sides of an electrode substrate, according to anembodiment of the invention.

FIG. 5 illustrates a base layer having an electrode formed on two sidesof an electrode substrate using embodiments of the invention.

DETAILED DESCRIPTION

According to embodiments of the invention, electrodes for energy storagedevices, such as lithium ion batteries, are fabricated using asolvent-free method and apparatus.

FIG. 1 illustrates a system 100 for fabricating electrodes by depositingbinder and active electrode material on one side of a substrate 102(otherwise known as a current collector in a finished electrode). Thesubstrate 102 can include in one example copper as an anode currentcollector or aluminum as a cathode current collector. In anotherexample, the anode current collector is a composite that includes forinstance steel. As other examples, substrate 102 could also include butis not limited to a nickel plated steel, a composite of fibrous carbon,a tin dioxide (SnO₂), and could be for instance a punched solid sheet oran expanded composite (i.e., having perforations that allow for an openexpansion of the substrate to reduce weight or allow higher mechanicalor material loading). However, the invention is not so limited and anysubstrate or collector material may be used to form an electrode havingother active material(s), according to what is known in the art. Theactive material or active material mixture includes but is not limitedto lithium titanate oxide (LTO), cobalt oxide, nickel oxide, manganeseoxide, nickel cobalt manganese oxide, iron phosphate, iron oxide,carbon, and silicon.

Substrate 102 is fed through a feed mechanism or roller system 104having a feed mandrel 106 that provides material for substrate 102 andwhich is guided by oppositely rotating guide mandrels 108. Inembodiments of the invention, substrate 102 may be a single sheet ofelectrode, or may be a continuous feed thereof. Substrate 102 is fedthrough a first application region 110 and through a second applicationregion 112 during which time mixes that may include binder, activematerial, and conductive material are applied or otherwise sprayed ontosubstrate 102. Heat is applied within application regions 110, 112,and/or after passing therethrough as will be further described, in orderto effect binding and formation of electrode materials. Substrate ispassed through a second set of guide mandrels 114 that guide thesubstrate, having active electrode material bound thereto, toward acollection mandrel 116. According to the invention, second set of guidemandrels 114 may be designed having a space or gap therebetween that ismaintained during operation in order to compress substrate 102 havingthe electrode thereon to a final desired and consistent thickness.

First application region 110 includes a device 118 for applying a firstlayer to substrate 102 that includes a spray mechanism (such as a spraygun or other known devices for causing a spray) that is configured tospray 120 a first or base layer of a mix of material onto substrate 102.In general, although first application region 110 is described as havinga spray mechanism or gun in order to apply material onto the substrate,and such is illustrated as “spray 120”, it is contemplated that anymechanism may be used to apply the material, to include painting,brushing, powder coating, using a fluidized bed, doctor blading, orwiping with a rag, as examples. In fact, in this and all subsequentapplication regions described, it is contemplated that a spray gun orother known spray device may be employed for applying first andsubsequent layers to the substrate 102, or any mechanism may be used toapply the materials, as described above, and that the term “spray” maybe applied to any mechanism or means that are used to apply a liquid toa surface.

According to the invention, device or spray mechanism 118 causes spray120 to emit between approximately 2 and 20 psi. According to theinvention, spray 120 includes a mix of binder, conductive carbon, andactive electrode material. The binder, according to one embodiment,includes a thermoplastic or a thermoset material, which in oneembodiment is polyvinylidene fluoride (PVDF) ranging between 6-85% byweight of the total material in spray 120. However the invention is notto be so limited, and for instance binder levels as low as 1% or as highas 100% may be used. Further, the invention is not limited to PVDF, butmay include any binder that is known within the art that include,according to embodiments of the invention and as stated, thermoplasticsand thermoset materials. As known in the art, thermoplastics are apolymer that becomes pliable above a certain temperature, and returns toa solid stated upon cooling. In contrast and as also known in the art, athermoset material forms an irreversible chemical bond during the curingprocess, which breaks down upon melting (and does not reform uponcooling). According to embodiments of the invention, the binder may bePVDF or any derivative thereof, or PTFE or any derivative thereof, asexamples. According to another embodiment of the invention, a very highmolecular weight polyethylene material may be included in the binder toadd structural integrity to the binder. The conductive carbon, as knownin the art, may be included in order to cause or enhance electricalcontact between particles within the electrode.

Spray 120 may also includes generally 4-8% conductive carbon to includea graphite such as TIMREX® KS6 (TIMREX is a registered trademark ofTimcal SA of Switzerland) (although increased amounts of conductivecarbon to 17% or higher and up to, for instance, 40% may be used,according to the invention). The balance % of spray 120 is activeelectrode materials which include but are not limited to LTO, cobaltoxide, nickel oxide, manganese oxide, nickel cobalt manganese oxide,iron phosphate, iron oxide, carbon, and silicon. As one example, spray120 includes 13% binder and 8% conductive carbon, and the balance ofspray 120 is 79% active material, by weight.

According to the invention, spray 120 deposited upon substrate 102within first application region 110 is heated in order to initiatebinding of the first layer mix to substrate 102. In one embodiment, aheater 122 is positioned opposite device 118 and adequate power isprovided to heater 122 to raise the temperature of substrate to betweenapproximately 100° F. and 500° F., and in one embodiment to 300° F.However, in another embodiment, a heater 124 is positioned to heat asurface of substrate 102 opposite a surface of substrate 102 to whichspray 120 is applied. In this embodiment as well, heater 124 is poweredto raise the temperature of substrate to between approximately 100° F.and 500° F., and in one embodiment to 300° F. Heat may also be applied,in one embodiment, via a heater 126 to the base layer after passingthrough first application region 110 at least until the first layer isvisibly molten, or begins to flow or wet, after which the first layermay be allowed to cool prior to applying a subsequent layer of electrodematerial. Thus, according to the invention, a first layer or base layerof electrode material is applied to substrate 102 and binding thereto isinitiated via one or both heaters 122, 124. The binder of base layer mayalso be melted throughout using heater 126 in order to cause the baselayer to melt and uniformly form on substrate 102. Heaters 122, 124, and126 may apply heat through any number of known mechanisms. For instance,heaters 122-126 may include infrared (IR) heaters, convective heaters,conductive heaters, radiant heaters (for instance, outside the IRspectrum), or induction heaters, as examples.

Heaters 122/124 and heater 126 generally serve different purposes. Forinstance, heaters 122/124 provide heat that is directed toward thesubstrate 102 in order that the binder material in contact withsubstrate 102 is caused to melt and flow and solidly adhere to substrate102. Heater 126, on the other hand, is generally directed toward heatingand causing to flow the bulk of the sprayed material that forms the baselayer. In such fashion, according to the invention, heat may be providedto either side of substrate 102, and heaters 122 and 124 may be providedat different locations relative to device 118, depending on such factorsas the amount of binder in spray 120. Thus, different types of heatersmay be used for the different desired type of heating to be performed.For instance, heaters 122 and/or 124 may be induction heaters that causeprimarily substrate 102 to heat, while heater 126 may be an IR,convective, or radiant heater. In another example, one or all heaters(122 and/or 124 and 126) are IR heaters. In fact, any combination ofheaters may be used, according to the invention, depending on thedesired type of heating to be performed (substrate versus a layer ofapplied material)

As known in the art, it is generally desired to maximize the amount ofactive material within the electrode. Thus, it is also desired tominimize the amount of binder used in spray 120, however under theconstraining guideline that adequate binding be obtained in the baselayer sprayed onto substrate 102 in first application region 110.Binding of the first layer of sprayed material 120 is affected by notonly the types of heaters, temperatures obtained, and the like, but alsoby the amount of binder, conductive carbon, and active material presentin spray 120. As known in the art, particle size may be activelyselected based on the type of electrode to be formed, and may range fromas low as nanometer-sized particles to hundreds of microns and greater.Particle size may also be varied throughout the depth of the electrode.As such, particle size of the active material influences not only theamount of active material that may be deposited in the base layer, butthe amount of binder as well and the amount of heat applied to initiatebinding of the base layer.

According to the invention, device 118 may include a spray gun having anelectrostatic charge applied thereto in order to guide and accelerateparticles in spray 120 toward substrate 102. Known spray mechanismsinclude an electrostatic charge that is applied typically proximate anozzle 128 of the spray gun 118 in order that the particles emittingfrom nozzle 128 are imparted with the charge, causing an electrostaticvoltage differential to form between nozzle 128 and substrate 102.According to one embodiment, the electrostatic voltage applied to nozzle128 is 25 kV, however the invention is not to be so limited and anyvoltage may be applied, above or below 25 kV, according to theinvention, in order that spray 120 is uniformly applied to substrate102. The voltage differential may be enhanced by grounding a region ofsubstrate 102 toward which spray 120 is directed. Because substrate 102is caused to pass continuously through first application region 110, itmay be inconvenient to directly ground substrate 102. Thus, according tothe invention, a support structure 130 may be provided over whichsubstrate 102 passes. Support structure 130 is stationary and inelectrical contact with substrate 102, thus grounding of substrate 102may be effected by providing a ground line 132 that is attached tosupport structure 130. According to one embodiment, multiple groundlines may be included (represented by a second ground line 134, but manymay be included according to the invention) in order to more uniformlyground substrate 102 proximate where spray 120 impinges thereon.

System 100 includes second application region 112 which causes a secondlayer to be deposited onto substrate 102. Second application region 112includes a device 136 (such as a spray gun or other known devices forcausing a spray, as described) that causes spray 138 to emit towardsubstrate 102 and land or impinge on the first layer applied in firstapplication region 110. Because adhesion from one electrode layer to thenext tends to be easier to achieve compared to the initial base layer tosubstrate 102, spray 138 for the second and any subsequent electrodelayers typically includes less binder. Thus, according to one embodimentof the invention, spray 138 includes 80-90% active material by weight(including but not limited to LTO, cobalt oxide, nickel oxide, manganeseoxide, nickel cobalt manganese oxide, iron phosphate, iron oxide,carbon, and silicon), 4-8% conductive carbon by weight, and the balanceas binder (PVDF in one embodiment). However the invention is not to beso limited, and for instance binder levels in the second electrode layer(and any subsequent layers) as well can be as low as 1% or as high as100%. In fact, any composition and percentage thereof of active materialand binder may be included, according to the invention, in the firstlayer and in the second and subsequent layers applied thereto.

According to the invention one or both heaters 140 may be included thatprovide heat to substrate 102. However, because substrate 102 alreadyhas a base layer thereon from first application region 110, heaters 140may not be necessary as the base layer also provides a thermallyinsulating barrier to be formed. Also, heaters 140 may not be includedbecause binding from one electrode layer to the next can be moreeffective and heat from a heater 142 may be adequate to cause thesubsequent electrode material from spray 138 to melt and flow when it isvisibly molten.

Heaters 140 (if used) and 142 may provide heat from any number of knownmethods, to include IR heaters, convective heaters, radiant heaters, orinduction heaters, as examples. Further, device 136 may also includespray mechanism having a nozzle 144 to which an electrostatic charge maybe applied as well, such as 25 kV. Application region 112 may include asupport 146 and one or more ground lines 148 for enhancing thedeposition of spray 138 onto the base layer previously applied.

According to the invention, system 100 includes a computer 150 with acomputer readable storage medium and having stored thereon a computerprogram comprising instructions to execute control commands via acontroller 152. In such fashion, controller 152 can be caused to controloperation of the spray stations, heaters, and roller mechanism as knownin the art and as described according to the operation above.

The operation of system 100 of FIG. 1 can be summarized in a set ofsteps within a block diagram 200 as illustrated in FIG. 2. Starting atstep 202, a substrate material is fed 204 and a first layer or baselayer of binder, conductive carbon, and active material is applied ontothe substrate at step 206. Heat is applied to the non-sprayed side ofthe substrate at step 208 and, as stated, may include a heaterimmediately opposite the location of the spray at step 206 andsimultaneous therewith, and/or heat may be applied to the non-sprayedside of the substrate after the substrate is caused to pass through aregion or zone where the base layer is applied. The spray side may thenbe heated at step 210 after which a first layer is formed on thesubstrate. A second layer of binder, conductive carbon, and activematerial is sprayed onto the first layer at step 212. As stated, thenon-spray side may be heated 214 with heaters immediately opposite thesecond spray region, or subsequent thereto as represented by heaters 140of FIG. 1. Heat may also be applied to the spray side 216 in order tocause the binder of the second layer to melt and flow. As alluded to,subsequent layers may be applied to the electrode layers by repeatingthe process described. That is, referring to FIG. 1, additional spraystations such as second application region 112 may be included,generally without limit, within system 100 in order to add additionallayers. Thus, at step 218, if additional layers are desired 220, blockdiagram 200 illustrates a return 222 in order that subsequent layers maybe added. In other words, return 222 does not represent physicallyreturning the part through second application region 112 but insteadillustrates that system 100 may include numerous spray stations in itsdesign in order to obtain a final desired thickness.

As also alluded to, each of the subsequent spray stations may include aspray mix of different quantities of binder, conductive carbon, andactive material, depending on the design of the desired final electrode.As known in the art, it may be desirable in one example to have agradient of particle sizes within a depth of an electrode where thesmallest active material particles are nearest the substrate and thelargest active material particles are toward the outer surface of theelectrode. Conversely it may be desired to have larger particlesproximate the substrate and smaller particles toward the outer surfaceof the electrode. Or, it may be desirable to have a uniform activematerial particle size throughout the electrode. Such designs aregenerally understood within the art and all may be formed according toembodiments of the invention. That is, thickness of each layer as wellas particle size within each layer may be selected and controlled assubsequent layers are added during the formation of the electrode inorder to achieve the desired particle size gradient of active materialwithin the electrode.

There may be several advantages to being able to build up amorphouslayers of varying material particle size or having different activematerials in an electrode. In one example layering larger particle sizescloser to the current collector, and progressively smaller particlesizes as the electrode thickness is built up away from the currentcollector, may allow for higher power and higher energy density andcycle life as compared to an electrode built from a single, bimodal ortrimodal particle size distribution that has been processed through asolvent cast method with a given binder. The process described wouldalso allow for varying the binder and conductive additives as necessaryto optimize the performance of the electrode for a given application.This would change the electrode active material matrix from an amorphousto more or less discreet layers with excellent interfacial conductivity.

This ability to layer without causing interfacial resistance is asignificant improvement over conventional solvent based technology andother known methods. The layering method described in this invention issuch that interfacial resistance is not apparent as one experienced inthe art would expect. In fact the resistance or impedance is lower thanis expected demonstrating that the method being disclosed is superior tothat of solvent based methods of applying active material to a currentcollector and is a significant improvement to the art.

Referring now to FIG. 3, electrode 300 includes a substrate 302 thatcorresponds to substrate 102 of FIG. 1. Electrode 300 includes one ormore layers of active material mix in binder 304 and, as stated, mayinclude a gradient of particle thicknesses throughout a thickness 306thereof. Electrode 300 may also have a total thickness 308 that iscontrolled by selectively applying the appropriate number of layers aswell as by compressing the substrate and layers as the finished productpasses through guide mandrels 114 as illustrated in FIG. 1. According tothe invention therefore, final single-sided electrode thicknesses of0.0005″ to 0.015″ or greater may be fabricated. In fact there is inprinciple no limit to how thin or how thick the electrode thicknessesmay be. In terms of thinness, a layer as thin as a single activematerial size may be achieved. In terms of thickness, limitations arebased only on the number of application stations and perhaps based onmore fundamental limits tied to electrochemical performance.

The principles described above with respect to FIGS. 1 and 2 can beapplied in order to fabricate two-sided electrodes. That is, a substratemay be passed through a system in which spray is applied to both sidesof the substrate and subsequent layers in order to cause active materialbuild-up on each side of the substrate. Referring now to FIG. 4, indouble-sided coating system 400, substrate 102 may be caused to movethrough a first double-sided coating station 402 to spray initial layerson each side of substrate 102. System 400 includes heaters 404 and asecond spray station 406 that is illustrative of stations that can beused, in conjunction with additional heaters 408 corresponding to arespective spray station 406. In other words, as with system 100 of FIG.1, multiple spray stations may be included within system 400 in order toform multiple subsequent layers in building up the double-sidedelectrode. System 400 may include heaters 410 on one or both sides ofthe substrate that cause the substrate to be pre-heated and therebyenhance heating of the substrate prior to spraying of the base layers oneach side, thereby enhancing adhesion of the base layers to thesubstrate 102. Spray mechanisms 412 may include electrostatic charge ornot, and one or more corresponding ground lines 414 may be included aswell. Heaters 410 and spray stations 412 may be staggered and offsetfrom one another, or positioned such that one of heaters 410 is oppositeone of spray stations 412, and the other of heaters 410 is opposite theother of spray stations 412, according to the invention. Second spraystation 406 likewise includes spray mechanisms 416 that may or may notbe electrostatically controlled, as well as grounded via ground lines tothe substrate (not shown in spray station 406).

In such fashion a double-sided electrode 500 may be formed havingsubstrate 102 and first active material layer 502 and second activematerial layer 504 formed thereon. As with the single sided embodiment,particle size gradients and overall thickness can be controlled usingthe appropriate particle size within each spray station and usingcompression mandrels 418. According to the invention therefore, finaldouble-sided electrode thicknesses of 0.0010″ to 0.030″ or greater maybe fabricated.

According to one embodiment, a metal belt 154 may be added to thecoating systems such as system 100 of FIG. 1. The metal belt may extendthe length of the system over which the substrate is caused to pass.That is, instead of using individual support structures 130 and 146, asingle belt may be provided to enhance grounding in the spray area(s) asthe substrate moves through. This may be of particular interest whenless conductive materials are used such as thin metals, compositestructures, open weave, foam-like, or non-woven substrates. Also, whensmall run lots of electrodes are desired, with the steel belt in place,the machine could be reversed to either build up electrode activematerial thickness or to possibly layer differing active materials toenhance final electrochemical performance. Another benefit of using abelt machine would be to allow free standing films of active material tobe made using the method so that these films could be used in otherapplications where a strong bond to a substrate or current collector isnot as strongly needed in the product design. The belt machine wouldalso allow for faster change over from electrode types.

Dual coating can be achieved by either applying active material on bothsides at once (i.e., FIG. 4), or by repeating single sided coating byrolling or flipping the web (i.e. re-running through the embodiment ofFIG. 1 with the reverse side of substrate 102 coated) and whether in avertical or horizontal fashion and either repeating the applicationzones or revisiting the application zones. That is, although FIGS. 1 and4 illustrate substrate 102 passing orthogonal to the earth gravitationalfield, according to the invention the substrate may be passed collinearwith the gravitational field. In other words, the system for coating maydrive the substrate in a vertical direction according to embodiments ofthe invention. Other methods to do the same would be to either make alonger machine with more stations or coil and uncoil the web againpassing through in the same direction, or taking the web back over themachine to save space. Lithium ion electrodes are therefore fabricatedwithout solvents, which perform as well as conventionally madeelectrodes using solvent processes. The electrodes can be made at anythickness, density and with any known active materials.

The process illustrated herein is not limited to very thin electrodes.Finished electrode thickness range from 0.0005″ to over 0.015″ (singlesided, and approximately double the thickness for double-sidedelectrodes) and thicker electrodes are possible, limited to an extentonly by the number of layering stations. Further, the process is notlimited to battery electrodes but may be extended to manufacturing aseparator layer in a similar fashion, enabling a full cell to bemanufactured on one line approaching a just in time delivery capability.

Electrode density is also be adjustable and controllable. A solvent-castelectrode typically includes coining to gain or improve performance.According to the invention, both coined and un-coined electrodes arefabricable from the process with no apparent difference in performance.A solvent cast system normally targets a 30-40% open structure aftercoining, and relaxation with cycling and polymer solvation will move theporosity back to the 50% range. However, the process illustrated hereincreates porosities from 15% to 50% with or without secondary coining.Not having to coin and experience the relaxation after solvation withelectrolyte addition thus improves overall cycle life. Further, theamount of binder is lowered in the internal structure of the activematerial relative to a solvent cast system. In a solvent cast system thepolymer binder often enters the internal structure of the activematerial. However, the process described maintains the majority of thebinder on the outside of the active materials, resulting in higherutilization of the active material when compared with the solvent castsystems.

In a solvent cast line, the solvent, normally N-Methyl-2-pyrrolidone(NMP), or methyl ethyl ketone (MEK), or other known solvents, aretypically added to the active material and then removed at a rate whichdoes not cause cracking or flaking of the cast electrode. This typicallyincludes extensive drying ovens and solvent recovery systems. Sometimesthe solvent will be used as part of the fuel to heat the oven. Eitherway the requirement to remove the solvent creates the need forextensively long drying ovens, >200 feet, and other chemical handlingequipment. Eliminating solvents in the casting process also reduces thepossibility of contaminating the electrolyte and cell when proper airingtime is not available.

Finally, the process illustrated herein does not alter the existingbattery chemistry. The same binders, active materials and conductiveadditives are used as in conventional solvent-based methods, with noother ingredients added. That is, the performance of the electrode interms of resistance, power, and fade rate are comparable to batteriesformed in a solvent-based system.

A technical contribution for the disclosed method and apparatus is thatit provides for a computer implemented dry, solvent-free method andapparatus for fabricating electrodes and, more particularly, to a methodand apparatus for manufacturing or creating lithium electrochemicalcells in a lithium-ion (Li-ion) battery.

One skilled in the art will appreciate that embodiments of the inventionmay be interfaced to and controlled by a computer readable storagemedium having stored thereon a computer program. The computer readablestorage medium includes a plurality of components such as one or more ofelectronic components, hardware components, and/or computer softwarecomponents. These components may include one or more computer readablestorage media that generally stores instructions such as software,firmware and/or assembly language for performing one or more portions ofone or more implementations or embodiments of a sequence. These computerreadable storage media are generally non-transitory and/or tangible.Examples of such a computer readable storage medium include a recordabledata storage medium of a computer and/or storage device. The computerreadable storage media may employ, for example, one or more of amagnetic, electrical, optical, biological, and/or atomic data storagemedium. Further, such media may take the form of, for example, floppydisks, magnetic tapes, CD-ROMs, DVD-ROMs, hard disk drives, and/orelectronic memory. Other forms of non-transitory and/or tangiblecomputer readable storage media not list may be employed withembodiments of the invention.

A number of such components can be combined or divided in animplementation of a system. Further, such components may include a setand/or series of computer instructions written in or implemented withany of a number of programming languages, as will be appreciated bythose skilled in the art. In addition, other forms of computer readablemedia such as a carrier wave may be employed to embody a computer datasignal representing a sequence of instructions that when executed by oneor more computers causes the one or more computers to perform one ormore portions of one or more implementations or embodiments of asequence.

According to one embodiment of the invention, a solventless system forfabricating electrodes includes a mechanism for feeding a substratethrough the system, a first application region comprised of a firstdevice for applying a first layer to the substrate, wherein the firstlayer is comprised of an active material mixture and a binder, and thebinder includes at least one of a thermoplastic material and a thermosetmaterial, and the system includes a first heater positioned to heat thefirst layer.

According to another embodiment of the invention, a solvent-free methodof manufacturing an electrode includes feeding a substrate through afeed mechanism, applying a first layer comprised of an active materialmixture and a binder to the substrate, wherein the binder includes atleast one of a thermoplastic material and a thermoset material, andheating the first layer with a first heater.

According to yet another embodiment of the invention, a computerreadable storage medium having stored thereon a computer programcomprising instructions which when executed by a computer cause thecomputer to cause a substrate to feed through an electrode fabricationsystem via a feed mechanism, apply heat to the substrate via a firstheater, and cause a first layer to be applied onto the substrate, thefirst layer comprised of an active material mixture and a binder, andthe binder includes at least one of a thermoplastic material and athermoset material.

This written description uses examples to disclose the invention,including the best mode, and also to enable any person skilled in theart to practice the invention, including making and using any devices orsystems and performing any incorporated methods. The patentable scope ofthe invention is defined by the claims, and may include other examplesthat occur to those skilled in the art. Such other examples are intendedto be within the scope of the claims if they have structural elementsthat do not differ from the literal language of the claims, or if theyinclude equivalent structural elements with insubstantial differencesfrom the literal languages of the claims.

What is claimed is:
 1. A solventless system for fabricating electrodescomprising: a mechanism for feeding a substrate comprising a currentcollector material through the system; a first application regioncomprising a first device for applying a first layer to the substratevia a dry dispersion application, wherein: the first layer comprises anactive material mixture, a binder, and a conductive material to thecurrent collector; and the binder comprises a thermoplastic materialand/or a thermoset material; and a first heater positioned to heat thefirst layer during and/or after application of the first layer to thesubstrate to bind the first layer to the substrate.
 2. The solventlesssystem of claim 1 wherein the first heater is positioned to heat asurface of the substrate that is opposite a surface of the substrate towhich the first layer is applied.
 3. The solventless system of claim 2wherein the first heater is positioned to heat the surface of thesubstrate within the first application region and while the first deviceapplies the first layer to the substrate.
 4. The solventless system ofclaim 2 wherein the first heater is positioned to heat the surface ofthe substrate after the first layer is applied to the substrate.
 5. Thesolventless system of claim 2 comprising a second heater positioned toheat the first layer after the first layer is applied to the substrate.6. The solventless system of claim 5 comprising: a second applicationregion comprised of a second device for applying a second layer to thefirst layer, wherein the second layer is comprised of the activematerial mixture and the binder; and a third heater positioned to heatthe second layer.
 7. The solventless system of claim 6 comprising athird device positioned within the first application region, the thirddevice configured to apply a third layer to the surface of the substratethat is opposite the surface of the substrate to which the first layeris applied.
 8. The solventless system of claim 1 wherein the bindercomprises polyvinylidene fluoride (PVDF).
 9. The solventless system ofclaim 1 wherein the first layer comprises a conductive additiveincluding carbon.
 10. The solventless system of claim 1 wherein thefirst layer ranges from 3-5% binder by weight.
 11. The solventlesssystem of claim 1 wherein the first device applies the first layer toeach of opposing sides of the substrate.
 12. The solventless system ofclaim 1 wherein the first device is an electrostatic spray gun.
 13. Thesolventless system of claim 1 further comprising at least one groundingwire that is electrically coupled to the substrate when the first deviceapplies the first layer to the substrate.
 14. The solventless system ofclaim 1 wherein the mechanism for feeding the substrate is a rollerassembly that comprises at least one mandrel used to compress thesubstrate after the base layer and the electrode layer have been appliedthereto.
 15. A non-transitory computer readable storage medium havingstored thereon a computer program comprising instructions which whenexecuted by a computer cause a processor to: cause a substratecomprising a current collector to feed through an electrode fabricationsystem via a feed mechanism; cause a first layer to be applied onto thesubstrate via a dry dispersion method, the first layer comprising anactive material mixture and a binder, and the binder comprising at leastone of a thermoplastic material and a thermoset material; and apply heatto the substrate via a first heater positioned to heat the first layerduring and/or after application of the first layer to the substrate tobind the first layer to the substrate.
 16. The computer readable storagemedium of claim 15 wherein the computer program instructions furthercause the processor to: apply heat to the first layer via a secondheater; cause a second layer to be applied onto the first layer, thesecond layer comprised of an active material and a binder; and applyheat to the second layer via a third heater.
 17. The computer readablestorage medium of claim 15 wherein the computer program instructionsfurther cause the processor to apply heat to the substrate with thefirst heater simultaneous with applying the first layer onto thesubstrate.
 18. The computer readable storage medium of claim 15 whereinthe computer program instructions further cause the processor apply heatto the substrate via the first heater after applying the first layeronto the substrate.
 19. A dry, solvent-free system for manufacturingbattery electrodes comprising: a first mechanism for advancing asubstrate comprising a current collector material; a first applicationregion arranged to receive the substrate and comprising a first devicefor coating a mixture of an active material and a polyvinylidenefluoride (PVDF) binder onto the substrate to form a base layer; a firstheater arranged to heat the base layer to cause the PVDF binder thereinto adhere the base layer to the substrate; a second mechanism foradvancing the substrate; a second application region arranged to receivethe substrate and comprising a second device for coating a second layeronto the base layer, the second layer comprising a mixture of an activematerial and a PVDF binder; and a second heater arranged to heat thesecond layer to cause the PVDF binder therein to adhere the second layerto the base layer; wherein the mixture of the active material and thePVDF binder in the base layer is independently controlled from themixture of the active material and the PVDF binder in the second layer,such that amounts of the active material and PVDF binder in the baselayer may differ from amounts of the active material and PVDF binder inthe second layer and the type of active material in the base layer maydiffer from the type of active material in the second layer.
 20. Thedry, solvent-free system of claim 19 wherein the first device isarranged to coat the mixture of the active material and PVDF binder ontoeach of opposing sides of the substrate.